KR101357637B1 - Horizontal shear connector for precast concrete bridge pier - Google Patents

Abstract

Horizontal shear connectors that connect circular pipes of different diameters to mesh with each other can be easily sheared in transverse directions to the foundation and coping sections of precast concrete piers to improve adhesion and constructability to concrete structures. Horizontal shear connectors for precast concrete piers are provided. A horizontal shear connector for precast concrete piers includes: a horizontal shear connector for transversely connecting the foundation and coping portions of the precast concrete piers, including: a first circular pipe having a plurality of first bars; And a second circular pipe having a diameter different from that of the first circular pipe and having a plurality of second reinforcing bars, wherein the first and second circular pipes having different diameters are connected so that the male and female are engaged with each other. The two reinforcing bars are projected and welded to the first and second circular pipes of the male and female so as to facilitate attachment to the concrete structure, respectively.

Description

Horizontal shear connector for precast concrete piers {HORIZONTAL SHEAR CONNECTOR FOR PRECAST CONCRETE BRIDGE PIER}

FIELD OF THE INVENTION The present invention relates to precast concrete piers, and more particularly, to horizontal shear connectors for transverse shear connection of foundations and copings in precast concrete piers.

Since the bridges that are constructed by on-site concrete pouring increase the construction period and cause environmental problems, such a construction method is decreasing in recent years, and as an alternative, a rapid construction method that prefabricates preformed segments on the site is frequently used. It is becoming.

For example, when the bridge is constructed in a place where rapid construction is required, such as downtown, this rapid construction method divides the bridge into several segments and assembles them on site, which not only shortens the overall construction period of the bridge. Environmental problems can be minimized.

When assembling the prefabricated segment as described above, a shear key must be installed and shear resistance must be exerted by mechanical engagement for shear connection at discontinuous surfaces existing between the segments. For example, in the case of a precast concrete segment, such a shear key is formed in the form of a protrusion on one side of the segment when the segment is manufactured. By the way, when producing a shear key of the protruding form on one side of the segment, when demolding the formwork, the shear key can be easily broken due to minor carelessness. In particular, the smaller the size of the shear key and the larger the protruding length, the more likely the breakage of the shear key is to occur during the segment manufacturing process. In addition, when the mold is demoulded because the concrete is not properly filled in the shear key forming portion of the formwork, the shear key is often not formed in the desired shape in the segment.

In addition, when the tension member is disposed continuously in neighboring segments, there is a possibility of leakage through the discontinuous surface between the segments. Leakage in the tension member installations occurring at the discontinuities between these segments, that is, the joints of the segments, can cause corrosion of the tension members, thereby causing damage to the tension members, which can cause serious problems for the entire structure such as collapse of the structure. Can be.

On the other hand, as a related art, Korean Patent No. 10-1039656 discloses the invention named "PSC pier and construction method thereof assembled from precast concrete segments having steel ducts and steel pipes," Figure 1 and It demonstrates with reference to FIG.

1 is a cross-sectional view showing a PSC pier assembled from a precast concrete segment having a steel duct and a steel pipe according to the prior art, Figure 2 is a perspective view showing the configuration of the pier foundation in FIG.

Referring to FIG. 1, a PSC pier 10 assembled from a precast concrete segment having a steel duct and a steel pipe according to the prior art includes a pier foundation 11, a precast concrete segment 12a, 12b, 12c, 12d), the pier pillar portion and the pier coping portion 13 laminated and assembled.

Pier base portion 11, as shown in Figure 2, is usually cast in the field, a plurality of shear connector 25 for the shear connection is inserted into the upper end to form the shear connector 25 protrudes to the upper surface do.

The pier foundation part 11 includes a plurality of foundation sheath pipes and steel wires 24 extending by the length of the pier to be inserted into the foundation sheath pipes, and the grooves for the segments on the upper and inner sides of the shear connecting member 25. 21) is formed. At this time, the groove for the segment 21 is chipped to facilitate the adhesion of the non-shrink mortar, the rubber pad 22 for maintaining the horizontal in the groove 21 and preventing leakage of the non-shrink mortar filling Is installed insert. At this time, at the end of the sheath pipe for the foundation is connected to the fixing fixture for fixing the steel wire 24. In addition, the top edge of the pier foundation 11 may be formed with a chamfer 23 to block the damage by the compaction equipment.

According to the PSC piers assembled from precast concrete segments with steel ducts and steel pipes according to the prior art, the shear connection using the steel duct of short length is installed on the pier foundation 11 and the segments 12a-12d. By doing so, it is possible to prevent an increase in construction cost, to facilitate the connection between the segments 12a to 12d and the pier foundation 11, and to prevent the shear failure of the joint portion. In addition, by inserting the steel wire support steel pipe for the independence of the steel wire between the steel wire and the sheath pipe, the steel wire upright by the steel wire support steel pipe at the time of stacking the segment can improve the workability and shorten the construction period.

On the other hand, when connecting the segment used in the piers pillars and the piers foundation, it is necessary to form a front end connected to the segment separately in the piers foundation. However, in the case of the pier foundation part, it is not easy to form the shear part because it is poured in the field, and this causes a problem in that the construction period is long.

As a prior art for solving the above-described problem, Korean Patent No. 10-952207 discloses a invention named "precast bridge and foundation connection structure and connection construction method", it will be described with reference to FIG. do.

Figure 3 is a cross-sectional view showing that the U-shaped sheath tube is applied in the bridge precast foundation according to the prior art.

Referring to FIG. 3, in a bridge precast foundation according to the related art, the precast member 30 has a front end portion 31 protruding from an upper surface thereof, and is formed in a cylindrical shape or a hexahedral shape, and in a transverse direction. After reinforcing the plurality of reinforcing bars 32 in multiple stages, the coupler 33 is coupled to both ends of each of the reinforcing bars 32, and the concrete is poured so that the coupler 33 is exposed to the side.

 At this time, the precast member 30 is provided with a longitudinal sheath tube for tension of the pier pillar portion, a longitudinal tension member 42 which is formed to extend as long as the pier length and is inserted into the longitudinal sheath tube and a fixing member for fixing the longitudinal tension member. do. At this time, the precast member 30 may be provided only with a U-shaped sheath tube 41 for the tension of the pier pillar portion.

Here, the reinforcing bars 32 are provided at intervals without interference with the installation of the coupler 33 and without interference with the longitudinal sheath tube, the longitudinal tension member and the anchorage. In addition, the precast member 30 may further rebar in the longitudinal direction.

According to the precast foundation for bridges according to the prior art, a precast member prefabricated so that the front end portion is formed integrally is installed on the ground, and then the rest of the foundation portion is placed on the side so as to be associated with the precast member. .

However, in the case of the precast foundation for bridges according to the prior art, a precast member prefabricated so that the front end is formed integrally is installed on the ground, but it does not use a horizontal shear connecting member that is a transverse shear of the base and the coping part, Or even when using such a horizontal shear connector has a problem that the adhesion to the concrete structure is low and the workability is poor.

1) Republic of Korea Patent No. 10-1039656 (application date: June 24, 2008), the title of the invention: "PSC pier assembled from precast concrete segment having steel duct and steel pipe and construction method thereof" 2) Republic of Korea Patent No. 10-952207 (Application Date: May 14, 2008), the title of the invention: "The connection structure and construction method of the precast piers and foundation" 3) Republic of Korea Patent No. 10-920204 (application date: September 12, 2008), the title of the invention: "Construction method of precast foundation for bridges" 4) Republic of Korea Patent No. 10-1029042 (application date: July 21, 2008), the name of the invention: "method construction method using a precast column unit using a sheath tube" 5) Republic of Korea Patent Publication No. 2005-117733 (published: December 15, 2005), the title of the invention: "Composite hollow bridge structure and its construction method using precast concrete formwork" 6) Republic of Korea Patent No. 10-971003 (application date: April 9, 2009), the title of the invention: "Forming for the cast casting and construction method of prefabricated bridge piers using the same" 7) Republic of Korea Patent Publication No. 2010-66856 (published: June 18, 2010), the title of the invention: "Prefabricated composite precast pier and construction method thereof capable of rapid construction"

The technical problem to be solved by the present invention for solving the above-mentioned problems is to use the horizontal shear connector to connect the circular pipe male and female of different diameters to be engaged with each other, the base portion and the coping portion of the precast concrete piers easily transverse It is to provide a horizontal shear connector for precast concrete piers, which can improve the adhesion and workability with the concrete structure by shear connection.

As a means for achieving the above-described technical problem, the horizontal shear connector for the precast concrete pier according to the present invention, in the horizontal shear connector for lateral shear connection of the base portion and the coping portion of the precast concrete pier, A first circular pipe having a first reinforcing bar; And a second circular pipe having a diameter different from that of the first circular pipe and having a plurality of second reinforcing bars, wherein the first and second circular pipes having different diameters are connected to be engaged with each other. And the second reinforcing bars are protruded and welded to the first and second circular pipes of the male and female so as to be easily attached to the concrete structures, respectively.

In this case, the horizontal shear connector is connected so as to engage the circular pipe male and female having a different diameter when connecting the base unit for level adjustment and the foundation precast concrete to provide a shear resistance.

Here, the horizontal shear connecting member is characterized in that it is located between the base unit for level adjustment and the foundation sheath pipe connecting the foundation precast concrete in the lateral direction.

The horizontal shear connector for precast concrete piers according to the present invention further comprises a rubber ring that is pre-inserted into the first or second circular pipe, the rubber ring being used for grouting the foundation sheath pipe. It is characterized by blocking the grouting material flowing between the adjustment base unit and the base precast concrete.

In this case, the horizontal shear connector is connected to the first and second coping portion precast concrete when the circular pipe male and female of different diameters are connected to provide a shear resistance.

Here, the horizontal shear connector is located between the coping portion sheath pipe connecting the first and second coping portion precast concrete in the lateral direction.

According to the present invention, by using a horizontal shear connector for connecting the circular pipe male and female of different diameters to engage each other, by easily shearing the base portion and the coping portion of the precast concrete piers in the transverse direction, The workability can be improved.

According to the present invention, by arranging the U-shaped sheath pipe in the level adjusting base unit, it is not necessary to form a fixing hole in the level adjusting base unit and insert the strand in advance, thereby improving the workability and economy of the precast concrete piers. Can be.

1 is a cross-sectional view of a PSC pier assembled from precast concrete segments with steel ducts and steel pipes according to the prior art.
FIG. 2 is a perspective view illustrating a structure of a pier foundation in FIG. 1. FIG.
Figure 3 is a cross-sectional view showing that the U-shaped sheath tube is applied in the bridge precast foundation according to the prior art.
4 is a cross-sectional view showing a precast concrete pier to which a horizontal shear connector according to an embodiment of the present invention is applied.
5 is a perspective view showing a precast concrete pier to which a horizontal shear connector is applied according to an embodiment of the present invention.
6A and 6B are a plan view and a cross-sectional view showing a foundation in a precast concrete pier to which a horizontal shear connector according to an embodiment of the present invention is applied, respectively.
7 is a cross-sectional view and a perspective view of a level adjustment bolt in a precast concrete pier to which a horizontal shear connector according to an embodiment of the present invention is applied.
8 is a view for explaining in detail the method of tensioning and fixing the U-shaped sheath pipe in the precast concrete pier to which the horizontal shear connector according to an embodiment of the present invention is applied.
9A and 9B are cross-sectional views and perspective views, respectively, of a U-shaped sheath pipe in a precast concrete pier to which a horizontal shear connector according to an embodiment of the present invention is applied.
10A and 10B are cross-sectional and perspective views, respectively, of a vertical shear connector in a precast concrete pier to which a horizontal shear connector according to an embodiment of the present invention is applied.
11A and 11B are perspective views of horizontal shear connectors for precast concrete piers, respectively, in accordance with an embodiment of the present invention.
12 is a view illustrating a pillar portion in a precast concrete pier to which a horizontal shear connector according to an embodiment of the present invention is applied.
FIG. 13 illustrates a coping portion in a precast concrete pier to which a horizontal shear connector according to an embodiment of the present invention is applied. FIG.
14 is a flowchart illustrating a precast concrete pier construction method to which a horizontal shear connector according to an embodiment of the present invention is applied.
15 is a flow chart showing a concrete foundation forming process in the precast concrete pier construction method to which the horizontal shear connector is applied according to an embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise.

Figure 4 is a cross-sectional view showing a precast concrete pier is applied to the horizontal shear connector in accordance with an embodiment of the present invention, Figure 5 is a perspective view showing a precast concrete pier is applied to the horizontal shear connector in accordance with an embodiment of the present invention.

4 and 5, the precast concrete pier to which the horizontal shear connector according to the embodiment of the present invention is applied includes a base part 100, a pillar part 300, and a coping part 400. The U-shaped sheath pipe 200 is seated on the foundation part 100, and the foundation part 100 and the pillar part 300 are connected to each other through the U-shaped sheath pipe 200.

The foundation part 100 includes the foundation level panel 110, the foundation unit 120 for level adjustment, the foundation precast concrete 130, the foundation expansion panel 140, the level adjustment member 150, and the spanner 160. ), The base sheath pipe (170a, 170b), the base horizontal shear connector (180a, 180b) and the base side anchorage 190.

The foundation level panel 110 may be formed in plural on the trench. After the plurality of foundation level panels 110 are protruded to form panel reinforcing bars on their side surfaces, and after leveling the foundation unit 120 for level adjustment and the foundation precast concrete 130, The mortar is filled through mortar injection holes formed in the upper part of the level adjusting base unit 120 and the foundation precast concrete 130, and the connecting reinforcing bars connect the plurality of foundation level panels 110, respectively. Done. At this time, the mortar injection hole is formed so as to penetrate in the height direction in the center of the plane of the level adjustment base unit 120 and the foundation precast concrete 130 is filled with the mortar.

Level adjustment base unit 120 has sheath pipes (170a, 170b) connected to the base horizontal shear connector (180a, 180b) on both sides, the sheath pipe (170a, 170b) is the foundation precast concrete It may be connected to the sheath tube formed in the 130 may penetrate the base strand (510). At this time, the sheath pipe formed in the foundation precast concrete 130 is formed so that one side extends from the foundation horizontal shear connector (180a, 180b) to the other side to the foundation anchorage (190).

Foundation precast concrete 130 is formed on the side of the level adjustment foundation unit 120, and is assembled with the level adjustment foundation unit 120 to form a foundation (100).

The foundation extension panel 140 is disposed below the foundation precast concrete 130, and the level and the height of the foundation precast concrete 130 are adjusted by the level adjusting member 150.

The level adjusting member 150 may be formed of, for example, a bolt head and a nut part as a level adjusting bolt. The level adjustment bolt 150 is composed of a bolt head and a nut, the bolt head is between the level adjustment base unit 120 and the foundation level panel 110 and the foundation precast concrete 130 And the base expansion panel 140, and the nut is welded to the level adjustment base unit 120 and the base precast concrete 130 by rebar, respectively. And integrated into the foundation precast concrete 130, respectively, and thus the level and height of the level adjustment foundation unit 120 and the foundation precast concrete 130 are used by the spanner 160. Can be adjusted by turning the bolt head from the side.

In addition, as shown in FIG. 5, a plurality of U-shaped sheath pipes 200 are formed, and each of the plurality of U-shaped sheath pipes 200 is disposed without interference with each other in the level adjusting base unit 120. In addition, the pillar portion is connected to the precast concrete 310. In this case, the column precast concrete 310 may be stacked adjacent to the column precast concrete (320).

In addition, the pillar portion 300 includes first and second pillar precast concrete (310, 320), pillar longitudinal sheath tube 330 and the circumferential connecting member.

The first and second columnar precast concretes 310 and 320 are segments, respectively, and the pillar part 200 may be formed by applying an adhesive to an upper surface of the segment and then stacking adjacent segments.

At this time, the column precast concrete (310, 320) has a column longitudinal sheath pipe 330 extending to the upper and lower column vertical shear connector (210, 220), the column longitudinal sheath The pipe 330 is connected to the plurality of U-shaped sheath pipes 200 disposed in the level adjusting base unit 120 so that the pillar portion strand 520 penetrates.

If the diameter of the pillar precast concrete (310, 320) is larger than the reference diameter, divided and transported in the longitudinal direction, and the pillar portion precast concrete (310, 320) with a circumferential connecting device at the site construction After connection, the pillar part 200 may be formed by stacking the pillar part precast concrete 310 and 320.

Here, the circumferential connecting device includes a reinforcing structure and a connecting bolt for connecting the divided column precast concrete (310, 320) in the circumferential direction, the reinforcing structure and the connecting bolt is a cross section for reinforcing the structure to the connecting portion To form a large, fastening of the connection bolt can be installed by adjusting the angle of 7 to 12 degrees not interfered by the length of the connection bolt.

If the diameter of the pillar precast concrete (310, 320) is smaller than the reference diameter (D), for example, 2.5m, the pillar portion 200 is manufactured by stacking as it is without a longitudinal division and laminated Can be formed.

In addition, the coping part 400 may include a first coping part precast concrete 410, a second coping part precast concrete 420, a coping part transverse sheath pipe 430, a coping part horizontal shear connector 440, and a nose. A ping-side side anchorage 450, a coping-up top anchorage 460, and a coping-section longitudinal sheath tube 470 are included.

The first and second coping precast concretes 410 and 420 are cast in place on top of the top pillar precast concrete 320 or precast to form the top surface 320 of the top pillar precast concrete. Stacked).

The first coping part precast concrete 410 includes a coping part longitudinal sheath tube 470 extending from the column vertical shear connector 220 to the top fixing part 450 of the coping part, and the coping part longitudinal direction. The sheath pipe 470 may be connected to the pillar longitudinal sheath pipe 330 of the pillar precast concrete 310 and 320 to penetrate the pillar strand 520. In addition, the first coping part precast concrete 410 is provided with a coping part transverse sheath pipe 430 extending to the coping part horizontal shear connector 440 on the left and right sides, the coping part transverse sheath pipe 430 ) May be connected to the sheath pipe formed in the second coping part precast concrete 420 so that the coping part strand 530 may pass through. At this time, the sheath tube formed in the second coping part precast concrete 420 extends from the coping part horizontal shear connector to the coping part side anchorage.

In addition, a drain pit 620 may be formed between the base portion 100 and the pillar portion 300, and an EL adjustment shoe block 630 is disposed on the coping portion 400. ) And EL fine adjustment mortar 640 can be formed.

In the case of precast concrete pier to which the horizontal shear connector according to an embodiment of the present invention is applied, it is preferable to connect with a stranded wire when the structure is connected with a steel rod because interference may occur due to the trench line. In addition, the tension material is tensioned sequentially, first 50% of the tension force is introduced, and then finally 50% of the tension force is introduced.

6A and 6B are a plan view and a cross-sectional view showing a foundation in a precast concrete pier to which a horizontal shear connector according to an embodiment of the present invention is applied, respectively.

In the precast concrete pier to which the horizontal shear connector according to the embodiment of the present invention is applied, the base portion 100, as shown in Figure 6a and 6b, for adjusting the level for coupling to the column portion 300 in the central portion The base unit 120 is disposed, and the U-shaped sheath pipe 200 is disposed in the base unit 120 for level adjustment.

A base level panel 110 is formed on a lower surface of the level adjusting base unit 120 to adjust the height and the level by the level adjusting member 150 of the level adjusting base unit 120. At this time, the base sheath pipe (170a, 170b) and the base portion horizontal shear connecting members (180a, 180b) are respectively installed on the side of the level adjustment base unit 120 in a direction perpendicular to each other. In addition, the base sheath pipes (170a, 170b) are connected to each other by the base side side anchoring device 190, and thereafter, the base sheath pipe (170a, 170b) is tensioned through the base strands 510.

That is, the level adjusting base unit 120 is provided with sheath pipes 170a and 170b connected to the base horizontal shear connectors 180a and 180b on both sides, and the sheath pipes 170a and 170b are the base parts. It may be connected to the sheath pipe formed in the precast concrete 130 to penetrate the foundation strand 510. At this time, the sheath pipe formed in the foundation precast concrete 130 is formed so that one side extends from the foundation horizontal shear connector (180a, 180b) to the other side to the foundation anchorage (190).

Accordingly, the level adjusting foundation unit 120 and the foundation precast concrete 130 are assembled to form the foundation 100, and the level adjustment foundation unit 120 and the foundation precast concrete ( 130 is connected to the base strand (510).

In addition, the foundation 100 is formed with a plurality of foundation precast concrete 130 on the side of the level adjustment foundation unit 120, the foundation sheath pipe (170a, 170b), foundation horizontal shear connector Are assembled to each other at 180a and 180b. That is, the foundation precast concrete 130 is formed on the side of the level adjustment foundation unit 120 is assembled with the level adjustment foundation unit 120 to form a foundation 100. In addition, each of the plurality of foundation precast concrete 130 is assembled to each other by the foundation sheath pipe (170a, 170b), the foundation horizontal shear connector (180a, 180b).

In addition, as shown in FIG. 6B, the foundation expansion panel 140 is disposed below the foundation precast concrete 130 and is formed by the level adjusting member 150 using a spanner 160. The level and height of the foundation precast concrete 130 is adjusted.

In addition, a plurality of U-shaped sheath tube 200, as shown in Figure 6b is formed, each of the U-shaped sheath tube 200 is disposed in the level adjustment base unit 120 without interference with each other, The pillar portion is connected to the precast concrete 310.

On the other hand, Figure 7 is a cross-sectional view and perspective view of the level adjustment bolt in the precast concrete pier to which the horizontal shear connector according to an embodiment of the present invention is applied.

In the precast concrete pier to which the horizontal shear connector according to the embodiment of the present invention is applied, the level adjusting member 150 is a level adjusting bolt, wherein the level adjusting bolt is a bolt head part 151 and a nut part 152. And a first steel plate 153, a first reinforcing bar 154, a welded part 155, a second steel plate 156, a third steel plate 157, a second reinforcing bar 158, and a protective cap Cap. However, it is not limited to this. In this case, the first steel plate 153, the first reinforcing bar 154 and the weld 155 are formed in the foundation level panel 110 or the foundation expansion panel 140, and the nut part 152, The second steel plate 156, the third steel plate 157, the second reinforcing bar 158 and the protective cap 159 is formed on the level adjusting foundation unit 120 or the foundation precast concrete 130, At this time, only the bolt head 151 which can be rotated through the spanner 160 is exposed in the lateral direction. At this time, the bolt head 151 rotates up and down through a screw thread, thereby adjusting the base unit 120 for level adjustment. Alternatively, the height and level of the foundation precast concrete 130 may be adjusted.

The level adjusting bolt 150 is composed of a bolt head 151 and a nut 152, and the bolt head 151 is disposed between the level adjusting base unit 120 and the base level panel 110. And between the foundation precast concrete 130 and the foundation expansion panel 140.

 The nut 152 is welded into the reinforcing bars 158 in the level adjusting base unit 120 and the base precast concrete 130, respectively, so that the level adjusting base unit 120 and the base precast concrete It is inserted into each of the 130 to integrate.

Accordingly, the level and height h of the level adjusting foundation unit 120 and the foundation precast concrete 130 are, as shown in FIG. 7B, by using a spanner 160 to secure the bolt head to the side. When turning 151, the level and height h of the level adjusting foundation unit 120 and the foundation precast concrete 130 are spaced apart from each other between the bolt head 151 and the nut 152. Can be adjusted.

On the other hand, Figure 8 is a view for explaining in detail the method of tensioning and fixing the U-shaped sheath pipe in the precast concrete piers to which the horizontal shear connector according to an embodiment of the present invention, Figures 9a and 9b respectively Sectional view and perspective view of a U-shaped sheath pipe in a precast concrete pier to which a horizontal shear connector according to an embodiment of the invention is applied.

Precast concrete bridge piers are applied to the horizontal shear connector according to an embodiment of the present invention, as shown in Figure 8, the base portion 100, the U-shaped sheath pipe 200, the pillar portion 300 and the coping portion ( And a base portion 100, a U-shaped sheath tube 200, a pillar portion 300, and a coping portion 400 assembled to each other, and a coping portion upper fixing unit of the coping portion 400. At 460, the pillar strand 520 is inserted. Thereafter, the column strand 520 is penetrated through the U-shaped sheath tube 200 to come out again to the other coping part upper anchorage 460, the column strand 520 is a plurality of U-shaped sheath tube. At 200 are respectively inserted and tensioned.

In addition, in the level adjustment base unit 120, as shown in Figure 9a, the base sheath pipe (170a, 170b) is disposed, the horizontal portion at the end of the base sheath pipe (170a, 170b) Shear connecting members 180a and 180b are disposed, and further, a U-shaped sheath tube 200 is disposed in the level adjusting base unit 120, and as shown in FIG. 9B, a plurality of U-shaped sheath tubes is provided. 200 is disposed so as not to overlap each other, in this case, the vertical shear connector 210 is disposed on the upper end of the U-shaped sheath tube 200.

Therefore, the precast concrete pier to which the horizontal shear connector according to the embodiment of the present invention is applied is disposed by the U-shaped sheath pipe 200, thereby not forming a separate anchorage in the foundation unit 120 for level adjustment, and also having a column strand. Since it is not necessary to insert 520 previously, workability can be improved.

10A and 10B are cross-sectional views and perspective views of a vertical shear connector in a precast concrete pier to which a horizontal shear connector according to an embodiment of the present invention is applied, respectively.

In the precast concrete pier to which the horizontal shear connector is applied according to an embodiment of the present invention, a plurality of vertical shear connectors 210 and 220 are disposed, and the vertical shear connector 210 disposed below the pillar part 300 is 10A and 10B, the U-shaped sheath pipe 200 may be disposed to be fastened to the upper portion and the lower portion of the pillar precast concrete 330. In addition, the vertical shear connector 220 disposed on the pillar portion 300 may be disposed to be fastened to the lower portion of the first coping portion precast concrete 410 and the pillar portion precast concrete 330.

10A and 10B, the vertical shear connector 210 disposed below the pillar part 300 may include a lower steel plate 211, a cast iron sleeve tube 212, an upper steel plate 213, and a stud ( 214) and a sheath pipe connection 215, and provide shear resistance when connecting the level adjustment base unit 120 and the column precast concrete 330.

Specifically, the vertical shear connector 210 disposed below the column part 300 is a column longitudinal sheath pipe 330 connecting the level adjustment base unit 120 and the column precast concrete 330. Located between, the structure is a male and female engagement by the reinforcing sleeve, has a shear resistance in the form of welding the stud 214 and the cast iron sleeve tube 212, respectively, for easy attachment. In addition, the vertical shear connector 220 disposed on the upper part of the column part 300 is a column longitudinal sheath pipe 330 connecting the first coping part precast concrete 410 and the column part precast concrete 330. Located in between.

In addition, the pillar vertical shear connector (210, 220) has a rubber ring (not shown) that is inserted in advance in the middle, the rubber ring grouting the reinforcing sleeve or the longitudinal longitudinal sheath pipe ( The grouting material that may flow between the level adjusting base unit 120 and the pillar precast concrete 330 at the time of grouting of the 330 is blocked.

In this case, each connection portion of the column precast concrete 330 prefabricated to have a lower portion of the plurality of pillar vertical shear connectors 220 and an upper portion of the plurality of pillar vertical shear connectors 210 is used for the level adjustment. By 1: 1 mutual coupling with the lower portion of each column vertical shear connector 210 provided on the upper surface of the foundation unit 120, the pillar precast concrete 330 is the foundation unit 120 for the level adjustment It is laminated on the upper surface of the.

In addition, the first coping portion precast concrete 410 of the coping portion 400 is located on the bottom surface corresponding to a position 1: 1 corresponding to the upper portion of the column vertical shear connector 220 of the column precast concrete 330 It is formed by inserting the portion 220 below the column vertical shear connector.

11A and 11B are perspective views of horizontal shear connectors for precast concrete piers, respectively, according to an embodiment of the present invention.

The horizontal shear connector 180 for precast concrete pier according to an embodiment of the present invention is a horizontal shear connector for transversely connecting the foundation part and the coping part of the precast concrete pier in a transverse direction, and a plurality thereof are disposed and are illustrated in FIG. 11A. As shown in the drawing, circular pipe male and female having different diameters 181 and 183, a first reinforcing bar 182 and a second reinforcing bar 184, and the level adjusting foundation unit 120 and the foundation precast concrete ( In the connection of 130, circular pipe males and females 181 and 183 having different diameters are connected to each other to provide shear resistance.

That is, the first circular pipe 181 is formed with a plurality of first reinforcing bars 182, the second circular pipe 183 has a different diameter than the first circular pipe 181, the plurality of second rebar ( 184). In this case, the first and second circular pipes 181 and 183 having different diameters are connected to each other so as to be engaged with each other, and the first and second reinforcing bars 182 and 184 may be easily attached to the concrete structure, respectively. Protruding welds to the first and second circular pipes 181 and 183 of the male and female have shear resistance.

Specifically, as shown in Figure 11b, the foundation horizontal shear connector (180a, 180b) is a foundation for connecting the level adjustment foundation unit 120 and the foundation precast concrete 130 in the side direction Located between the sheath pipe (170a, 170b), wherein the foundation horizontal shear connector (180a, 180b) is connected to each other so that the circular pipe male and female (181, 183) of different diameters, respectively, the level is a concrete structure The first and second reinforcing bars 182 and 184 are protruded and welded, respectively, to facilitate the attachment of the adjustment base unit 120 and the foundation precast concrete 130 to have shear resistance.

In addition, the base horizontal shear connector (180a, 180b) is each provided with a rubber ring (not shown) that is inserted in advance in the middle, wherein the rubber ring is grouting of the base sheath pipe (170a, 170b) In operation, the grouting material flowing between the level adjusting base unit 120 and the base precast concrete 130 is blocked.

Similarly, the horizontal shear connector 440 is connected to engage circular pipe males and females having different diameters when the first and second coping precast concrete 410 and 420 are connected as shown in FIG. 13 to be described later. To provide shear resistance, wherein the horizontal shear connector 440 is positioned between the coping portion sheath pipe 430 connecting the first and second coping portion precast concrete 410, 420 in a lateral direction. .

On the other hand, Figure 12 is a view illustrating a pillar portion in a precast concrete pier to which a horizontal shear connector according to an embodiment of the present invention is applied.

In the precast concrete pier to which the horizontal shear connector according to the embodiment of the present invention is applied, as shown in FIG. 12, the first and second pillar precast concretes 310 and 320 are pillars. Sub longitudinal longitudinal sheath tube 330 and the circumferential connecting member 340, but is not limited thereto.

Each of the first and second pillar precast concretes 310 and 320 may form a pillar portion 200 by applying an adhesive to an upper surface of the segment as a segment and then stacking adjacent segments. At this time, at least one pillar precast concrete may be laminated.

The pillar precast concrete (310, 320) has a column longitudinal sheath pipe 330 extending to the upper and lower column vertical shear connector (210, 220), the column longitudinal sheath pipe ( 330 is connected to the plurality of U-shaped sheath tube 200 disposed in the level adjusting base unit 120 so that the pillar portion strand 520 penetrates.

At this time, when the diameter of the pillar precast concrete (310, 320) is larger than the reference diameter, for example, 2.5m, the column is divided and transported in the longitudinal direction, the column circumferential connecting device 340 at the time of construction site After connecting the secondary precast concrete (310, 320) to form the pillar portion 200 by stacking the pillar precast concrete (310, 320).

The circumferential connecting device 340 includes a reinforcing structure and a connecting bolt (not shown) for connecting the divided column precast concrete 310 and 320 in the circumferential direction, and the reinforcing structure and the connecting bolt are connected to each other. Form a large cross section for the reinforcement of the pillar portion 300, the fastening of the connection bolt can be installed by adjusting the angle of 7 to 12 degrees not interfered by the length of the connection bolt.

In addition, when the diameter of the pillar precast concrete (310, 320) is smaller than the reference diameter (D), for example, 2.5m, the pillar portion 200 is manufactured by stacking as it is without a longitudinal division and laminated Can be formed. At this time, each of the pillar precast concrete (310, 320) is provided with the vertical shear connector (210, 220) is assembled in advance.

Meanwhile, FIG. 13 is a view illustrating a coping part in a precast concrete pier to which a horizontal shear connector according to an embodiment of the present invention is applied.

In the precast concrete pier to which the horizontal shear connector according to the embodiment of the present invention is applied, the coping part 400 is, as illustrated in FIG. 13, the first coping part precast concrete 410 and the second coping part precast. Concrete 420, coping part transverse sheath pipe 430, coping part horizontal shear connector 440, coping part side fixture 450, coping part upper fixture 460 and coping part longitudinal sheath pipe 470 Include. Here, the coping portion horizontal shear connector 440 is substantially the same configuration as the above-described base horizontal shear connector (180a, 180b), the diameter of the circular pipe male and female 441, 443, the first reinforcing bars 442 having different diameters And a second reinforcing bar 444, wherein the first and second coping precast concretes 410 and 420 are connected to each other so that circular pipe males 441 and 443 having different diameters are engaged with each other so as to engage the shear resistance. to provide.

The first and second coping precast concretes 410 and 420 are cast in place on top of the top pillar precast concrete 320 or precast to form the top surface 320 of the top pillar precast concrete. Can be stacked on each).

The first coping part precast concrete 410 includes a coping part longitudinal sheath tube 470 extending from the column vertical shear connector 220 to the top fixing part 450 of the coping part, and the coping part longitudinal direction. The sheath pipe 470 may be connected to the pillar longitudinal sheath pipe 330 of the pillar precast concrete 310 and 320 to penetrate the pillar strand 520.

In addition, the first coping part precast concrete 410 is provided with a coping part transverse sheath pipe 430 extending to the coping part horizontal shear connector 440 on the left and right sides, the coping part transverse sheath pipe 430 ) May be connected to the sheath pipe formed in the second coping part precast concrete 420 so that the coping part strand 530 may pass through. At this time, the sheath tube formed in the second coping part precast concrete 420 extends from the coping part horizontal shear connector to the coping part side anchorage.

The second coping part precast concrete 420 is coupled to the first coping part precast concrete 410. In this case, a coping part transverse sheath pipe 430 is formed in each of the first and second coping part precast concrete 410 and 420, and is connected to each other by the coping part horizontal shear connecting member 440. The coping part strand 530 is inserted into the coping part transverse sheath tube 430 by the ping part side fixing part 450 and is tensioned, and the column part strand 520 is coping part by the coping part upper fixing part 460. It can be inserted into the longitudinal sheath tube 470 and tensioned.

On the other hand, Figure 14 is an operational flow diagram of the precast concrete pier construction method according to an embodiment of the present invention, Figure 15 is an operation flow diagram showing a concrete foundation forming process in the precast concrete pier construction method according to an embodiment of the present invention. .

14 and 15, the precast concrete pier construction method according to an embodiment of the present invention, the emergency construction of the precast concrete pier consisting of the base portion 100, the column portion 300 and the coping portion 400 As a method, first, a level adjusting base unit 120 is provided on a plurality of base level panels 110, and a plurality of level adjusting members 150 are provided on the side of the level adjusting base unit 120, respectively. By adjusting the level and height of the base unit for adjusting the level 120 ( S110 ). At this time, the level adjustment base unit 120 is mounted in advance a plurality of U-shaped sheath pipe (200).

Specifically, the adjustment of the level and height of the level adjusting base unit 120, as shown in FIG. 15, first to break the trench, and install the base level panel 110 on the top ( S111 ). The level adjusting bolt 150 is installed at a fixed position on the base level panel 110 ( S112 ). Thereafter, the level adjusting base unit 120 is installed on the base level panel 110 ( S113 ), and the level adjusting bolt 150 is adjusted using the spanner 160 to adjust the level. After adjusting the level and height of the base unit 120 ( S114 ), and after adjusting the level and height of the base unit 120 for level adjustment, the base level panel 110 and the base unit for level adjustment The gap between the 120 is treated with a grouting material 610 ( S115 ).

Next, a plurality of foundation precast concretes are connected to the level adjustment foundation unit using a foundation strand and a foundation horizontal shear connecting member, and the plurality of level adjustment members in terms of the plurality of foundation precast concretes. By adjusting the respective to adjust the level and height of the plurality of foundation precast concrete ( S120 ).

Specifically, in the adjustment of the level and height of the plurality of foundation precast concrete, as shown in FIG. 15, a plurality of foundation expansion panels 140 are provided on the side of the foundation level panel 110, respectively. ( S121 ). Subsequently, the foundation precast concrete 130 is sequentially disposed on the side surface of the level adjusting base unit 120 ( S122 ), and the level adjusting bolts 150 are adjusted using the spanner 160, respectively. By adjusting the level and height of the foundation precast concrete 130 ( S123 ), and insert the foundation strand 510 in the anchorage 190 formed on the end side of the foundation precast concrete 130 to tension ( S124 ).

The plurality of level adjusting members 150 are level adjusting bolts, and the level adjusting bolts are respectively formed on the side of the level adjusting base unit 120 and the side of the plurality of foundation precast concrete 130. The height and the level of the level adjusting base unit 120 and the plurality of foundation precast concrete 130 may be adjusted by turning using the.

Next, a plurality of pillar vertical shear connectors 210 for shear connection of the foundation part 100 and the pillar part 300 are formed on the upper surfaces of the plurality of U-shaped sheath pipes 200, respectively. The column precast concrete 310 is connected to the top of the sheath tube 200 ( S130 ), and the pillar precast concrete 310 is laminated on the level adjusting base unit 120 ( S140 ). In this case, the U-shaped sheath tube 200 may serve as a fixing anchorage and may not need to separately install a fixing unit under the level adjustment base unit 120, thereby improving workability and economic efficiency.

Next, the first and second coping precast concrete 410 and 420 which are divided from each other by using the coping part strand 530 and the coping part horizontal shear connector 440 in the coping part side fixing unit 450 ( S150 ).

Next, the coping part 300 is tensioned by tensioning the column strand 520 passing through the U-shaped sheath pipe 200 and the column vertical shear connectors 210 and 220 in the upper coping part upper fixing unit 460. Fix it ( S160 ).

Therefore, according to an embodiment of the present invention, by using the horizontal shear connector to connect the circular pipe male and female of different diameters to engage each other, by easily shearing the base portion and the coping portion of the precast concrete piers transversely, the concrete structure It can improve the adhesive force and workability of the.

The foregoing description of the present invention is intended for illustration, and it will be understood by those skilled in the art that the present invention may be easily modified in other specific forms without changing the technical spirit or essential features of the present invention. will be. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is shown by the following claims rather than the above description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

100: foundation
200: connection portion (U-shaped sheath tube)
300: pillar portion
400: coping part
110: foundation level panel
120: base unit for level adjustment
130: foundation precast concrete
140: foundation expansion panel
150: level adjusting member (level adjusting bolt)
160: spanner
170a, 170b: foundation sheath tube
180a, 180b: foundation horizontal shear connector
190: foundation side anchorage
210, 220: column vertical shear connector
310: first pillar precast concrete
320: second column precast concrete
330: longitudinal longitudinal sheath tube
340: circumferential connecting member
410: first coping part precast concrete
420: second coping part precast concrete
430: coping part transverse sheath tube
440: coping portion horizontal shear connector
450: coping part side anchorage
460: coping part upper anchorage
470: coping part longitudinal sheath tube
510: foundation strand
520: column strand
530: coping part strand

Claims (6)

In a horizontal shear connector for shearing the foundation and coping of the precast concrete piers transversely,
A first circular pipe having a plurality of first rebars formed therein; And a second circular pipe having a different diameter from the first circular pipe and having a plurality of second reinforcing bars, wherein the first and second circular pipes having different diameters are connected to be engaged with each other, and the first And the second reinforcing bars are protruded and welded to the first and second circular pipes of the male and female so as to facilitate attachment with the concrete structure, respectively, and have a shear resistance.
The horizontal shear connector is connected so that the circular pipe male and female of different diameters are engaged when the leveling foundation unit and the foundation precast concrete are connected to provide shear resistance,
The horizontal shear connector is a horizontal shear connector for precast concrete piers, characterized in that located between the leveling base unit and the base sheath pipe connecting the foundation precast concrete in the lateral direction. delete delete The method of claim 1,
Further comprising a rubber ring pre-inserted into the first or second circular pipe,
The rubber ring blocks the grouting material flowing between the level adjustment base unit and the base precast concrete during grouting of the base sheath pipe, horizontal shear connector for precast concrete piers. The method of claim 1,
The horizontal shear connector is a horizontal shear connector for precast concrete piers, characterized in that the connection of the first and second coping precast concrete is connected to engage the circular pipe male and female of different diameters to provide a shear resistance. 6. The method of claim 5,
The horizontal shear connector is a horizontal shear connector for precast concrete piers, characterized in that located between the coping portion sheath pipe connecting the first and second coping portion precast concrete in the lateral direction.

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